about
DAO1 catalyzes temporal and tissue-specific oxidative inactivation of auxin in Arabidopsis thalianaphot1 inhibition of ABCB19 primes lateral auxin fluxes in the shoot apex required for phototropismArabidopsis H+-PPase AVP1 regulates auxin-mediated organ development.Brachytic2/ZmABCB1 functions in IAA export from intercalary meristemsROOT ULTRAVIOLET B-SENSITIVE1/weak auxin response3 is essential for polar auxin transport in Arabidopsis.Job Sharing in the Endomembrane System: Vacuolar Acidification Requires the Combined Activity of V-ATPase and V-PPase.A plasma membrane H+-ATPase is required for the formation of proanthocyanidins in the seed coat endothelium of Arabidopsis thaliana.The Arabidopsis concentration-dependent influx/efflux transporter ABCB4 regulates cellular auxin levels in the root epidermis.Auxin transport.Endocytotic cycling of PM proteins.The SAUR19 subfamily of SMALL AUXIN UP RNA genes promote cell expansionFlavonoids and auxin transport: modulators or regulators?Directed plant cell-wall accumulation of iron: embedding co-catalyst for efficient biomass conversionSeven things we think we know about auxin transport.From perception to attenuation: auxin signalling and responses.Immunolocalization of PIN and ABCB Transporters in Plants.Non-invasive quantification of endogenous root auxin transport using an integrated flux microsensor technique.Enhanced gravi- and phototropism in plant mdr mutants mislocalizing the auxin efflux protein PIN1.Over-expression of the Arabidopsis proton-pyrophosphatase AVP1 enhances transplant survival, root mass, and fruit development under limiting phosphorus conditions.Shade-avoidance responses in two common coastal redwood forest species, Sequoia sempervirens (Taxodiaceae) and Satureja douglasii (Lamiaceae), occurring in various light quality environments.The circadian clock rephases during lateral root organ initiation in Arabidopsis thalianaArabidopsis ROOT UVB SENSITIVE2/WEAK AUXIN RESPONSE1 is required for polar auxin transport.Evidence of oxidative attenuation of auxin signalling.Identification, purification, and molecular cloning of N-1-naphthylphthalmic acid-binding plasma membrane-associated aminopeptidases from Arabidopsis.Increased glutathione biosynthesis plays a role in nickel tolerance in thlaspi nickel hyperaccumulators.ABCB19/PGP19 stabilises PIN1 in membrane microdomains in Arabidopsis.Arabidopsis P-glycoprotein19 participates in the inhibition of gravitropism by gravacin.PGP4, an ATP binding cassette P-glycoprotein, catalyzes auxin transport in Arabidopsis thaliana roots.Reduction of benzenoid synthesis in petunia flowers reveals multiple pathways to benzoic acid and enhancement in auxin transport.Measure for measure: determining, inferring and guessing auxin gradients at the root tip.Detection of herbicides in the urine of pet dogs following home lawn chemical application.Differential effects of sucrose and auxin on localized phosphate deficiency-induced modulation of different traits of root system architecture in Arabidopsis.Gene expression profiling reveals defined functions of the ATP-binding cassette transporter COMATOSE late in phase II of germination.Vesicular cycling mechanisms that control auxin transport polarity.Assessment of plants from the Brassicaceae family as genetic models for the study of nickel and zinc hyperaccumulation.Antimicrobial effect of synergistic interaction between UV-A light and gallic acid against Escherichia coli O157:H7 in fresh produce wash water and biofilmRelocalization of the PIN1 auxin efflux facilitator plays a role in phototropic responsesInteractions among PIN-FORMED and P-glycoprotein auxin transporters in ArabidopsisVesicle trafficking: ROP-RIC roundaboutAuxin regulates adventitious root formation in tomato cuttings
P50
Q27315181-DFA0C8E9-3FF2-4C3E-8C29-FC9A543343A5Q28743893-BA7D87D6-52C0-46EB-9A1C-DB0EF2007BDCQ33341663-6A120B46-8A39-4841-97BD-AACC6ADCC64EQ33349334-AA9979BD-9DDD-4AB8-BFBA-560E76C7DD66Q33355669-3BC14E4E-EE2C-4979-BC1A-F96BBE31612AQ33361956-695379D7-3838-45C2-8299-9C940E03A955Q33849828-5C406EE7-E509-4ED6-82F2-2F98A44B82A9Q34223490-BA1F0E06-D9E9-4312-8181-150B7098100AQ34438427-96636D21-D426-4B82-9183-DB64DB33454CQ36110964-F8D87F05-229B-4109-B79F-A61CECD4D485Q36349904-04FE8EAB-A010-4804-9ED3-20C918329DDBQ37058342-8EFC2EA7-E864-4105-9F18-C1ECAE05730CQ37355833-C4598554-3835-43E5-9740-F2DCF14034FBQ37866934-74A7EE4E-7D87-442F-9EE9-25F2DA8D47A7Q38134180-38F4C13F-78E6-4FC4-8917-F386FB507C45Q38932824-6D77D9F4-3320-4A3D-8296-FAD3795985FCQ39236540-FB9314B5-41C0-4A09-8EC6-8D6E3D863C77Q39307880-4A02871B-5A9F-41FC-B2B8-928179CB6FEAQ41236900-E9012441-0E46-4F94-8423-97FC7C97C047Q41665450-45EB2538-A30A-41B3-8C00-6FA819D60CE8Q41870567-87EB5FDC-AC82-413C-A354-D50A0A08732EQ43706915-94DA5130-E0E5-4579-9404-4195962EBEE6Q43724289-CF0B5568-28B7-4B73-888C-1D552FB46C96Q43916184-DFC5732C-6228-4CF3-8FB0-15DD8E0A6A16Q44989826-E05E77DA-1F26-45A2-A401-19CF4B8CA3D7Q46386005-12219D30-9AAB-48BD-9857-815EC2CBD586Q46559318-938EACB4-B2BE-4CFC-A6F5-3A7A84394A23Q46769503-7A869959-94D6-4F93-962D-57013DB99A26Q48082584-94E29A84-81E4-4A3C-8196-6F37D248D500Q50459636-AA05A376-5337-4ECA-BE2C-B09E14A9F481Q50481835-C67C7C64-377D-478A-B68C-BE2B9E4732DAQ51991348-71C9C5D4-D84C-43B3-A6DF-B8DE3FD5C04AQ51993492-D08697C1-1262-4290-B477-694B0DC0E47AQ52102574-EA205564-A6CE-4773-94DA-C90377A8705CQ54512919-57CA1B79-A44E-42BF-A9A4-F5C6C561E163Q57807573-247735DF-3BFA-4149-B8FE-5148FA9F733DQ75286363-2D32E4D4-66B1-4FD9-8A64-B4CA6886CCB4Q79609521-539471EE-5BCA-439F-87E7-7A36C8C46300Q84629563-B673C22F-E487-448C-906F-B27C4B913B77Q90871831-D0FCD6C8-2D06-409D-8137-1B3406106247
P50
description
hulumtuese
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researcher
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wetenschapper
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հետազոտող
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name
Wendy Peer
@ast
Wendy Peer
@en
Wendy Peer
@es
Wendy Peer
@nl
Wendy Peer
@sl
type
label
Wendy Peer
@ast
Wendy Peer
@en
Wendy Peer
@es
Wendy Peer
@nl
Wendy Peer
@sl
prefLabel
Wendy Peer
@ast
Wendy Peer
@en
Wendy Peer
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Wendy Peer
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Wendy Peer
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P1053
H-2970-2013
P106
P21
P31
P3829
P496
0000-0003-0046-7324